Hookah

ABSTRACT

The present invention includes a check valve on or about the stem of hookah that re-directs wetted smoke through the conduit that primarily supplies dry smoke into a hookah bottle.

RELATED APPLICATIONS

This application is a continuation, and claims priority under 35 U.S.C. §120 from U.S. patent application Ser. No. 15/063,503 titled Hookah filed on Mar. 8, 2016.

FIELD OF THE INVENTION

The present invention relates to the field tobacco smoking devices and more specifically to the field of hookahs.

BACKGROUND

Of the many proud traditions of Ottoman culture, few have achieved the world-wide fame of hookah smoking. Once confined to the Middle East and Near East regions, the hookah's notoriety was invigorated by Napoleon's invasion of Egypt and the stream of curious Westerners which followed thereafter. Painters, such as Eugene Delacroix and Jean-Leon Gerome, when depicting Oriental styles typically included a hookah as a symbol of the depicted culture. The hookah was elevated from a regional curiosity to a universal symbol of sophistication.

The hookah, which has maintained a constant popularity in the Middle East, presently enjoys in American culture a unique, niched function. Hookah smoking combines community and relaxation into a single event. Rarely does one witness a group smokers crowded about a single cigarette, cigar, or pipe. Though hookahs are often designed with a single smoke outlet; the presence of multiple hoses, each capable of simultaneous use, emanating from a single smoking instrument is unique to the hookah. Multiple hose hookahs form the centerpieces of hookah clubs in which hookah smokers gather to unwind and converse with other community members. A hookah combines fashion, art, and function into a single device.

A basic hookah includes a base, a pipe, at least one hose with a mouthpiece, and a bowl. The hookah bowl holds the hookah tobacco, frequently “massell.” Massell is a mixture of tobacco, molasses, and often a flavor or fruit extract. The molasses and fruit extract add a substantial amount of moisture to the massell that is missing in conventional tobacco. This added moisture makes massell more sensitive to the elements relative to conventional tobacco; prolonged exposure to air evaporates much of the moisture of massell and reduces its flavor. When properly protected, massell allows a smoker a more recreational, flavored smoke than the tobacco of cigars, cigarettes, pipes, and the like. An experienced hookah smoker will know to loosely distribute massell into a pile within the hookah bowl to allow heat to evenly circulate through the pile.

The heat that ignites the massell derives from coals positioned above the hookah bowl. The coals and massell preferably never contact one to the other. A common method of placing coals proximate to the massell involves spreading a foil upon the top of a hookah bowl, punching holes in the foil, and then placing the coals onto the foil. The heat from the lighted coals travels through the holes in the foil to ignite portions of the massell. Particulates from the massell travel in the smoke created by the ignition down through the hookah bowl into the hookah pipe.

The hookah pipe is the body of a hookah and is usually fabricated from brass, tin, or stainless steel. The pipe transports the massell smoke from the bowl to the hookah base, which is a cavern containing water. The base of the hookah is typically fabricated of glass or plastic and tends to be the most expressive portion of the hookah, ranging from translucent to wildly-colored. Within the cavern of the hookah base, the massell smoke is cooled by the water within. The cooled massell smoke then returns to the back to the pipe, though not through the same entrance by which the massell smoke enters the base. From the pipe, the massell smoke travels through the hose and out of the mouthpiece.

There are presently two prominent versions of hookah structures: the Lebanese style and the Egyptian style. Although the aficionado will explain that there are many differences between the two styles, the practical layman would quickly note the obvious difference: the connection point between the pipe and the hookah bowl. The Egyptian style hookah pipe tapers upward into what is generally referred to as a male connection. The Egyptian style hookah bowl includes a female connection which receives the pipe's male connection. In the Lebanese style hookah the bowl has the tapered male connection and the pipe has the female connection to accept the Lebanese style hookah bowl. In both styles, to allow a more airtight connection a collar is generally added to fit around the male connection.

Although hookahs are growing more advanced, there are still troubles common to hookahs. One of the greatest impediments to hookah smoking enjoyment is the problem of aggregated, stale wetted smoke. The stale, wetted smoke sits in the path of fresh smoke, the density frustrating the internal gas flow dynamics of the hookah and the taste of the wetted smoke corroding the fresh smoke as it passes through the stale cloud. The present invention goes a long way towards solving this lingering, troublesome issue.

SUMMARY

The present invention is directed to a hookah. The hookah includes a hookah bottle and hookah stem. The hookah stem includes a primary stem, which further includes a plenum and a burner support. The bottle holds liquid for cooling wet smoke and has a bottle interior and a bottle neck.

The primary stem, positioned above said bottle neck, is adapted to hold a hookah burner. The interior of the stem includes a central, substantially-vertical dry smoke conduit bounded by a dry smoke inlet and a lower dry smoke outlet formed by a transverse stem wall. A wet smoke conduit bounded by a wet smoke inlet and a peripheral wet smoke outlet is positioned above the bottle neck. The hookah stem further includes a down tube, affixed to the dry smoke outlet and further defines the dry smoke conduit. The down tube terminates in a lower dry smoke release aperture and forms a peripheral wet smoke intake. The down tube is dimensioned to extend into the hookah bottle to a penetration depth at least half of a bottle's height.

The stem further includes a pressure-actuated check valve, co-planar to the bottle and in gaseous communication with the dry smoke conduit of the stem. A wet smoke entry is exposed to the bottle interior and adapted to be selectively impeded, during neutral and negative bottle pressure events, and allow, during positive bottle pressure events, gaseous communication from the wet smoke entry to the wet smoke intake. A hose fitting, affixed to the wet smoke outlet, permits the releasable affixation of a hookah hose to the hookah stem.

The present invention further includes a method for smoking a hookah. The method includes downwardly drawing indirectly-combusted tobacco smoke from a hookah burner into an elongate dry smoke conduit of the hookah stem into a liquid within the interior of a hookah bottle using the hookah hose releasably affixed to, and in gaseous communication with a wet smoke conduit of, the hookah stem. Then one aggregates a substantial amount of wetted tobacco smoke within the hookah bottle above the liquid and below the transverse wall of the hookah stem. Then one urges air from the hookah hose through the wet smoke smoke conduit into the bottle interior to create positive bottle pressure. Wetted tobacco smoke is directed into the pressure-actuated check valve, co-planar with said bottle and in gaseous communication with the dry smoke conduit of the stem, with a wet smoke entry exposed to the bottle interior and adapted to selectively impede, during neutral and negative bottle pressure events, and allow, during positive bottle pressure events, gaseous communication from the wet smoke entry to the wet smoke intake. Wetted tobacco smoke is directed upwardly through the dry smoke conduit toward and through the hookah burner.

An embodiment of the present invention may further include a check valve located about the primary stem. The primary stem includes a pressure-actuated check valve in gaseous communication with the dry smoke conduit of the stem. A wet smoke entry is exposed to the bottle interior and adapted to be selectively impeded, during neutral and negative bottle pressure events, and allow, during positive bottle pressure events, gaseous communication from the wet smoke entry to the wet smoke intake. A hose fitting, affixed to the wet smoke outlet, permits the releasable affixation of a hookah hose to the hookah stem.

These aspects of the invention are not meant to be exclusive. Furthermore, some features may apply to certain versions of the invention, but not others. Other features, aspects, and advantages of the present invention will be readily apparent to those of ordinary skill in the art when read in conjunction with the following description, and accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side isometric view of the hookah of the present invention.

FIG. 2 is a side, exposed isometric view of the hookah of the present invention.

FIG. 3 is an upper, exposed isometric view of the stem components of the present invention.

FIG. 4 is a side, exposed orthographic view of a hookah of the present invention.

FIG. 5A is a side, exposed orthographic view of a down tube of the present invention.

FIG. 5B is a side, detailed orthographic view of a down tube and valve of the present invention.

FIG. 6A is a side, exposed orthographic view of a stem of the present invention.

FIG. 6B is a side, detailed orthographic view of a down tube and valve of the present invention.

FIG. 7A is an upper, isometric view of a down tube of the present invention.

FIG. 7B is a side, exposed view of a down tube and valve of the present invention.

FIG. 7C is a side, exposed view of a down tube and valve of the present invention.

FIG. 8 is an upper, isometric view of a hookah bowl of the present invention.

FIG. 9 is a side, exposed view of a hookah bowl of the present invention.

FIG. 10A is an upper isometric view of a valve of the present invention.

FIG. 10B is a lower isometric view of a valve of the present invention.

FIG. 11A is a side isometric view of a down tube, valve, and plug of the present invention.

FIG. 11B is a side isometric view of a down tube, valve, and plug of the present invention.

FIG. 12 is a view of the method of the present invention.

FIG. 13 is an upper, perspective view of the hookah of the present invention.

FIG. 14 is an upper, exposed view of the hookah of the present invention.

FIG. 15 is a partial, exposed view of the hookah of the present invention.

FIG. 16 is a partial, exposed view of the hookah of the present invention.

FIG. 17 is an upper, perspective view of the hookah of the present invention.

FIG. 17A is an upper, perspective view of a portion of the hookah of the present invention.

FIG. 17B is an upper, perspective view of a portion of the hookah of the present invention.

FIG. 18 is a side, plan view of the hookah of the present invention.

FIG. 19 is a side, exposed view of the hookah of the present invention.

FIG. 20 is a partial, exposed view of the hookah of the present invention.

FIG. 21 is a partial, exposed view of the hookah of the present invention.

FIG. 22 is a side, plan, exploded view of the hookah of the present invention.

FIG. 23 is an upper perspective, exploded view of the hookah of the present invention.

FIG. 24 is an upper perspective view of the hookah of the present invention.

FIG. 25 is a side, plan, revealed view of the hookah of the present invention.

FIG. 26 is a partial, exposed view of the hookah of the present invention.

FIG. 27 is a partial, exposed view of the hookah of the present invention.

FIG. 28 an exposed view of the hookah of the present invention.

DETAILED DESCRIPTION

Referring first to FIGS. 1-3, a basic embodiment of the hookah 100 of the present invention is shown. The hookah includes a stem 110 and a bottle 102. The bottle 102 can be conceptually subdivided into at least two regions for the purposes of the present disclosure, an interior 104 and a neck 106. The bottle 102 may be constructed of any material commonly used in the fabrication of hookah bottles, and the bottle may feature a generally unlimited series of shapes and dimensions. The bottle 102 includes a solid sidewall 108 that holds liquid (not shown) for the cooling of tobacco smoke. The bottle 102 is generally bulbous for the retention of a substantial amount of water. The neck 106 of the present invention is the portion of the bottle upon which a stem is usually attached, either internally or externally and begins at the apex of the bottle and continues until the point at which the bottle flares into the bulbous portion of the bottle, the hookah body 112. The bottle interior 104 includes the volume of the hookah bottle bounded by the hookah sidewall, and it should be noted that there is not necessarily a clear boundary of a hookah “neck.” For purposes of the present disclosure, the hookah neck spans from the apex of the hookah bottle, to the lower of: the point of the hookah bottle wherein the bottle first begins to flare outward (to increase the volume and lower the center of mass for the stability necessary to support the hookah mass), or the point below where the stem affixes to the hookah bottle in a manner that forms an airtight seal between the stem and neck. In the hookah of FIG. 1, for example the apex of the hookah is the point where stem and bottle form an airtight seal, but because the bottle begins to flare outward just adjacent to the lower point of the primary stem. The bottle and the stem of a hookah are separable, and in the embodiment of FIG. 1 join via an interference fit through the use of a compressible seal 184.

The stem 110 can be conceptually subdivided into three components, the burner support 120 and plenum 130 (together which form the “primary” stem), and a down tube 140, which supplements the dry smoke conduit 190 of the primary stem. The burner support 120 and a stem plenum 130 may, or may not, be separable as described in U.S. Pat. No. 7,806,123, the disclosure of which hereby incorporated into the present disclosure. Generally speaking, the burner support 120 is discernable from the stem plenum 130 by function; the burner support generally contains only dry smoke that is transported from the hookah burner downward, while the plenum 130 includes complex airflow passages for the shunting of both wet smoke and dry smoke to their respective destinations. Again, the use of terminology such as “plenum” and “burner support” is not to imply that the features are clearly distinct one from the other, or that the components are separable; instead, such terms are descriptive supports to aid in explaining the present invention. The burner support holds a hookah burner/bowl, or such other arbitrary components that further extend the height of the hookah having a dry smoke conduit and a position for the burner. The hookah of FIGS. 1-3 has a compressible seal 184 for the interference fit affixation of a burner to the burner support, as well as a shield 180 for the deflection/collection of ashes away from the hookah body. The stem plenum includes one or more wet smoke apertures 132, shown here as a hose fitting, which as described in U.S. Pat. No. 8,001,978 (the disclosure of which hereby incorporated into the present disclosure), may be for the purpose of drawing smoke to a user (e.g., a hose fitting) or wet smoke pressure release. Hose fittings 132 may be releasably affixed to the stem plenum 130, preferably by means of mating threading on an end of the hose fitting and the wet smoke outlet 134 of the plenum 130. The purpose of the hose fitting is to releasably affix a hookah hose thereto. Although a hookah hose is a significant component of the hookah, for purposes of the present invention, the hose need not be considered other than that it is a source of positive or negative gaseous flow into the hose fitting and plenum. Therefore, a hookah hose need not be detailed to understand the present invention.

The hookah bottle 102 includes a solid sidewall because unlike other smoking instruments, which lack an ornamental nature, the stem contains the necessary airflow elements. The hookah bottle 102 has an opening bounded by the neck 106 for the stem 110 to send and receive smoke. The stem attaches to the hookah bottle through any means known in the art, including seal, threading, clasps, etc; and may attach at any position known in the art, such as within a hookah bottle neck, outside the hookah bottle neck, or atop the hookah bottle neck.

Dry smoke begins at the burner (not shown), enters the dry smoke inlet 192 and travels through the dry smoke conduit 190 of the burner support 120. From the burner support 120, dry smoke enters the stem plenum 130 where it may or may not be immediately directed to the down tube 140. In any case, the dry smoke enters the stem plenum 130 through a channel that further forms the dry smoke conduit 190. In the hookah embodiment of FIG. 3, for example, the plenum lacks internal channeling that defines the dry smoke conduit; instead, the dry smoke conduit is further formed by the down tube 140. The dry smoke conduit in most hookahs is effectively formed of two components: the burner support 120 and the down tube 190, the latter of which shunts dry smoke through the plenum with an interior ostensibly entirely dedicated to the acceptance of wet smoke rising from the bottle, an elevated wet smoke cavern. The hookah embodiment of FIG. 3 can be contrasted with the hookah embodiment of FIG. 4, which includes a plenum with internal channeling defining both dry smoke conduit 190 and wet smoke conduit 136. Sidewalls 170 of the hookah of FIG. 3 “contain” or “have” the dry smoke conduit, whereas the sidewalls 170 of the hookah of FIG. 4 define the wet smoke conduit 136 (as an elevated wet smoke cavern) and dry smoke conduit 190. The present invention may be used with either type of hookah, or some other variety.

It is preferred in the present invention that the down tube 140 include an attachment means, e.g. threading, pressure-fit, clasp, etc., for attaching the down tube to the dry smoke outlet 196 primary stem. By dry smoke outlet 196 it is meant the aperture through which dry smoke exits the primary stem for its descent into the hookah bottle 102. Placing a down tube 140 at the apex of the plenum 130, as shown in FIG. 3, permits greater variations in, and simplified, wet smoke channeling within the base stem with less materials removal therein during fabrication. Returning to FIGS. 1-3, the dry smoke travels through the down tube 140 into the hookah bottle 102 as it exits the down tube dry smoke release 198; and in the presently discussed embodiment, the dry smoke is segregated from the wet smoke conduit by transport through the down tube within the plenum 130.

As shown in FIG. 4, when the dry smoke is released from the down tube 140 into the hookah bottle 102, the liquid 902 cools the smoke. The smoke ascends through the liquid 902 and is released above the surface of the liquid to become wetted smoke 904 in the bottle interior. The wetted smoke ascends from the bottle interior into the stem base so long as there is negative pressure in the hookah bottle interior, relative to the dry smoke conduit. By negative pressure (with reference to the bottle interior), it is meant pressure less than that of equilibrium. During negative pressure events, gas is drawn from the interior of the hookah bottle to the plenum and out the hose fitting through the wet smoke conduit. Hookah smoking is a negative pressure event. By neutral pressure (with reference to the bottle interior), it is meant that the pressure of the hookah bottle interior is in substantial equilibrium with the dry smoke conduit. A user achieves a neutral pressure event by refraining from drawing gas from the hookah or blowing air into the hookah through the hose fitting. By positive pressure (with reference to the bottle interior), it is meant pressure greater than that of equilibrium, relative to the dry smoke conduit. During positive pressure events, gas is blown from the hose fitting through the wet smoke conduit to the interior of the hookah.

One of the great problems confronting hookahs, and their users, that is not shared by other smoking implements is the aggregation of stale, wetted smoke 904. Although the purpose of a hookah is to deliver wetted smoke to a user's mouth, smoke that spends a substantial length of time in the hookah interior without being drawn into the plenum becomes “harsh” and undesirable. Unfortunately, of the gases present in the hookah, wetted smoke is the densest—and therefor most challenging to move and/or expel. Therefore drawing a hookah with stale, aggregated wet smoke draws fresh smoke into the liquid, and then subsequently up into the plenum. However, the density of the stale smoke prevents a “first in, first out” scenario; instead, significant quantities of the newly-drawn smoke is likely to be drawn toward the user, and drawn through the stale smoke, into the plenum. A cloud of aggregated wet smoke creates a layer of undesirable gaseous tobacco that affects each draw of smoke that passes through it. Multiple solutions have been attempted to purge a hookah of the ultra-dense stale smoke.

For users of hookahs exemplified by the figures of U.S. Pat. No. 7,806,123, the disclosure of which is hereby incorporated by reference, the hookahs include no mechanical means of controlling pressure loss. The hookahs leaked unless manually stopped from doing so. Unfortunately, the denser the smoke, the less the likelihood that the smoke would simply dissipate upward through the hookah hose. Users tended to place a finger on the aperture of a hookah hose to prevent leakage anyway. To purge a hookah of stale smoke, one user would blow at a very calculated rate into the hookah hose to attempt to push the wetted hookah smoke from the bottle interior. This met with some success; however, because dry air from a human is less dense than wetted, tobacco smoke, gas that exited the hookah through an autoseal pressure gate was a mixture of human breath and wetted smoke, mostly the former. The blow rate was highly calculated because if not forceful enough, the wetted smoke would not be sufficiently urged to leave in significant quantity and the exiting gas would be composed highly disproportionately of human breath. If the user blew too forcefully, a portion of gas would exit the autoseal gate, but yet another portion would operate the hookah in reverse to compress the liquid in the bottle sending liquid up the dry smoke conduit and squirting water out through the hookah bowl—extinguishing the coals and ruining the tobacco.

Then the hookahs of the '978 patent appeared; although these hookahs solved the hookah leakage issues during neutral pressure events, the solution for purging the interior of the hookah bottle remained the same. Further compounding the issue of purging a hookah is the myriad of internal dimensions of a hookah stem and bottle. During a state of equilibrium, wetted smoke behaves according to the principles of Brownian motion and will achieve a generally uniform Brownian distribution within the stem base interior. During states of positive pressure (e.g., blowing into the stem base) and negative pressure (e.g., sucking from the stem base), the pressurized wetted smoke behaves according to the principles of Bernoulli and the Continuity Equation. Wherein ρ is fluid density, A is cross section area, v is velocity, and time is time:

P(A1)v1(Δt)=ρ(A2)v2(Δt)

The entire volume of a hookah stem and hookah bottle capable of retaining wetted smoke is of consequence—although open volumes are of greater consequence than constricted volumes (e.g., wet smoke channels). The complex smoke shunting avenues of a hookah are located in the stem. Even the in the revolutionary '978 patent, the patent depicts a hookah having autoseal gates, either independent or combined into a hose fitting, that are located above where dense smoke would naturally aggregate. Wetted smoke aggregates around the surface of the liquid within a hookah bottle; whereas wetted smoke egress points tend to be in the lower portion of the stem. Gas blown into a hookah from a hose fitting starts at the entry point of the hose fitting, usually the periphery of the base of a stem; from there the gas travels throughout the open volumes of a hookah. Although there will almost always be a downward open volume from the hose fitting, often there is a significant upward open volume that may generate a spiraling downward force acting to nullify any upward force from the liquid surface. The force of gas in the direction of the liquid surface to the point of exit is the most consequential force in the purging process. The present invention offers two significant solutions: (i) the invention provides internal contouring that permits the efficient use of internal forces, and (ii) the invention changes the point of exit to a central position that is also co-planar to the bottle rather than a point high in the stem.

The present invention features a pressure-actuated check valve 150 preferably positioned co-planar to the bottle. In other words, the preferred check valve is located on the configured hookah of the present invention in a position whereby a horizontal line that intersects the check valve 150 would necessarily intersect the hookah bottle 102. A check valve is a backflow prevention device: it allows flow in only one direction. The pressure of forward fluid flow opens the valve and the pressure from backflow closes it, forcing the stopper, whether the stopper includes a gate, ball, wall, etc., against the valve seat. The preferred location for the check valve is affixed to exterior or interior of the down tube. The check valve may be integrated into the down tube; and in instances wherein the stem recedes well into the hookah neck, the check valve may be integrated into the stem. The check valve of FIG. 2 depicts a ball check valve. The ball check valve features a body 152 having a wet smoke entry 154 and a wet smoke intake 156. The body defines a frustoconical void wherein a floating spherical stopper 158 utilizes merely the force of gravity to form a one-way seal during negative pressure events within the bottle. During positive pressure events, gas travels from the wet smoke inlet 138 down the wet smoke conduit 136 and through the wet smoke inlet 138 and into the bottle interior. The pressure accumulation reaches the entry to the valve, the wet smoke entry 154, and urges the stopper 158 upward into the larger diameter of the void thereby permitting gaseous flow from the wet smoke entry 154 to the wet smoke intake 156. The wet smoke entry offers gaseous communication between the bottle interior and the valve; the wet smoke intake offer gaseous communication between the valve and the dry smoke conduit 190. The valve may directly access the dry smoke conduit 190 of the down tube 140 or the dry smoke conduit of the primary stem, depending on which location is most convenient and accessible.

A hookah is a unique smoking instrument in that there are multiple avenues of gas flow within the device, and there is a central gas collection point from which gas is distributed. The present invention exploits an avenue of gas transfer as a purge route not utilized by existing hookahs, the avenue by which dry smoke is delivered to the bottle. During a positive pressure event, the check valve 150 allows gas into the dry smoke conduit 190 and the pressure forces the gas up the dry smoke conduit, through the stem, and then out through the dry smoke inlet 192. From the dry smoke inlet 192, gas passes into the outside environment through the burner (not shown). So for the purposes of the present invention, certain conventional terms such as “dry smoke conduit” should be viewed in context to be understood. Conventional hookahs utilize a dry smoke conduit solely for the unidirectional delivery of dry smoke. The present invention alters this convention, and allows during select periods, wet smoke to enter the “dry smoke conduit” for purposes of purging the wetted smoke. Furthermore, directing wetted smoke into the usually narrower dry smoke conduit permits less force to be used to purge the wetted smoke. Wet smoke collecting in a narrow conduit is less troublesome than wetted smoke collecting in a larger volume because the wetted smoke is more easily urged from one direction to another. Wetted smoke not purged in the dry smoke inlet would settle as the lowest point of the down tube that remains above the liquid surface. Highly pressurized air from the dry smoke conduit may even force a substantial amount of wetted smoke back into the liquid.

Another differentiating aspect of hookah smoking is the use of a specialized burner. Specifically, the burners utilized in connection with hookah stems have inherent structural intricacies that, although designed to prevent tobacco from falling into the hookah stem, happens to be an admirable structure for exhaust of smoke. Hookahs burners (also known as “bowls”), although varying from brand-to-brand, tend to have a number of similar features as shown in FIGS. 8-9. The hookah burner 202 as depicted includes the most common feature of hookah burners, a platform with multiple tobacco smoke apertures 206. Furthermore, the burners 202 often include a void 212 below the tobacco platform with a substantially greater diameter than the dry smoke inlet 190. The hookah burner depicted includes a spire that works in concert with a plate 204 for holding coals. Although such a burner is proprietary and rare, there is a parallel to be drawn with more conventional hookah burners that utilize a foil rather than a solid, perforated plate. Even hookah bowls that utilize a single aperture, which is usually raised to prevent tobacco from falling into the hookah stem, tend to utilize some manner of multi-punctured self-supporting sheet. Alternatively, as exemplified by U.S. Design Pat. No. 618,389, the disclosure of which is expressly incorporated into this application, the hookah bowl may include horizontal apertures. Whether the hookah burner possesses multiple vertical apertures, a sizable void, and/or one or more horizontal apertures, these features, when applied in reverse, act to disperse and/or muffle the force of purged gas being exhausted through an unconventional exit point.

Turning now to FIG. 4, the present invention also contemplates a plunging hookah stem 102. By plunging hookah stem it is meant that the hookah stem 102 includes a plenum 130 that defines the wet smoke conduit 136 and the dry smoke conduit 190. Such stems generally are less simple to discern between the plenum and the burner support, mostly because such distinctions are less useful in describing the internal features. Plunging hookah stems have certain disadvantages over stems with elevated wet smoke caverns because the wet smoke conduits must be created within the sidewall 170, usually with a boring instrument. These conduits are usually sinuous, meaning for the purposes of this disclosure, that they include at least one change of direction (i.e., are non-linear). The sidewalls 170 of hookahs with elevated wet smoke caverns, as shown in FIG. 2, permit direct, linear wet smoke conduits to be constructed. Both the hookah stem embodiments of FIGS. 2-4 feature a sidewall with a tranverse wall 172, simply located in different positions. By sidewall it is meant a barrier of the plenum with respect to the outside environment; by transverse wall it is meant a sidewall portion having a substantially horizontal portion to a degree that permits a down tube to be affixed thereto (for releasable down tubes), or extend therefrom (for unitary down tubes). The preferred down tube 140 releasably affixes to the dry smoke outlet 196; however, the down tube 140 can be integrated into the stem. The significant feature of the down tube is that it extends down into the hookah bottle 102 to distance equal to at least half of the hookah bottle's height H, and that the down tube is the point of the stem at which the stem, upon being approximately co-planar with the bottle, projects minimal mass into the hookah bottle. The stem serves several functions, including structural support and structural stabilization. As the portion of the stem that need not be a barrier against glancing blows (because it is within the bottle) nor affix to the bottle to provide stability, the down tube needs only the mass to continue to shunt dry smoke into the hookah bottle. The stem of FIG. 4 utilizes a ball check valve having a body 152 forming a void with an elevated ceiling. Upon encountering a positive pressure event, gas enters the wet smoke entry 154 the stopper 158 is urged upwards to a position above the wet smoke intake 158.

Turning now to FIGS. 5A-5B, the down tube 140 may have affixed externally thereto the check valve 150. Another acceptable version of check valve includes a swing gate as an operative element 158. The body 152 of the check valve forms a central void and element shoulders 159. During negative and natural pressure events, a swing gate 158 is pressed or rests against, respectively, the element shoulders. During positive pressure events, gas enters the wet smoke entry 154 and urges the swing gate, which may or may not have a spring return, to and allow gaseous communication between the bottle interior and the dry smoke conduit through the wet smoke intake 156.

FIGS. 6A and 6B depict the ball check valve 150, which may be externally affixed to the down tube 120. The body 152 of the check valve forms a central frustoconical void. During negative and natural pressure events, the spherical stopper 158 is pressed or rests against, respectively, the narrower portion of the void. During positive pressure events, gas enters the wet smoke entry 154 and urges stopper upward and allow gaseous communication between the bottle interior and the dry smoke conduit 190 through the wet smoke intake 156.

FIGS. 7A-7C depicts a check valve 150 integrated into the down tube 120. Down tubes are inherently low-mass structures and by nature lack the volume in which to embed a valve. The preferred means of integrating a valve into a down tube is by increasing the mass by use of raised blisters into which the valve is embedded. The check valve 150 version depicted in FIGS. 7A-7C is a lift check valve. The body 152 of the check valve forms a central void and element shoulders 159. During negative and natural pressure events, a lift gate 158 is pressed or rests against, respectively, the element shoulders. During positive pressure events, gas enters the wet smoke entry 154 and urges the lift gate, which may or may not have a spring return, into a lift gate void 157 to and allow gaseous communication between the bottle interior and the dry smoke conduit through the wet smoke intake 156 The check valve of the present invention may interact with the stem of the present invention in order to perform its task; the attachment to a down tube, for example, may be external, integrated, or internal. It is preferred that the attachment is external, or integrated if easily accessible, because the valves may require cleaning from time to time.

The particular version of the check valve utilized with the present invention is not an overriding factor. Other forms of valves that permit one-way gaseous communication capable of achieving the purposes of the present invention may be freely utilized. The position of the check valve 150 is a significant factor of the present invention, the closer that the valve can be positioned to the surface level of liquid within a hookah bottle, the better. Unfortunately, a product supplier does not control the amount of liquid that a hookah user places within the hookah bottle. A product supplier may, however, provide visual cues as to the appropriate height of a liquid. These visual cues may be placed on the bottle exterior or may be based on the lowest surface of the valve or provided on the down tube.

Turning now to FIGS. 10A-B, a preferred version of the check valve 150 includes a clean out means. By clean out means, it is meant a way of accessing the internal structures of the valve. An example of a clean out means includes a valve having a bifurcated body 152 such that a portion of the body is removable therefrom. The valve may include a valve lid 151 and removal means 153, such as a slit for a screwdriver or coin. The lid 151 may be affixed to the body 152 through any common attachment mechanisms such as interference fitting, threading, pressure fit, etc. The lid may be located, when a ball valve having a frustoconical void is used, towards the major diameter of the valve void such that the spherical stopper may be removed that the void formed by the body 152. Massell smoke is not only corrosive, but it is also highly adherent. Periodic soaking of the spherical stopper in a specialized solvent aids the invention in having a lengthy lifespan.

Turning now to FIGS. 11A-B, the present invention may utilize a check valve 150 that is removably affixed to a down tube 140. There may be situation wherein the valve is not desired to be used, or the valves may be interchangeable based on circumstances. In the valve version shown, because the down tube 140 extends vertically into the base of a hookah bowl and the valve extends roughly perpendicular therefrom, the use of a gravity-based valve is a non-preferred option. Instead a valve 150 that accommodates a roughly horizontal airflow from the wet smoke entry 154 to a wet smoke egress point of the valve, shown here as a wet smoke exit 172, and then into the wet smoke intake 172, preferably utilizes a swing gate valve (as shown in FIG. 5A-B). The body 152 of the valve 150 releasably affixes to the down tube via the wet smoke intake. The body of the valve adjacent to the wet smoke exit 172 may be threaded to mate with threading on the wet smoke intake 156. Again, any affixation mechanisms known in the art may be utilized to join the valve to the down tube, including press fit and interference fit. Furthermore, the present invention may feature a down tube plug 170. The down tube plug 170 is an impediment adapted to fit into the wet smoke intake 156 when a valve does not occupy the wet smoke intake. The wet smoke intake may include any of the affixation mechanisms of the valve, and preferably utilizes whatever affixation mechanism is utilized by the valve body 152. As with the previously discussed lid, the body of the valve and plug may include a removal means, such as a cavity dimensioned to accept a screwdriver bit.

The invention further includes a method for smoking 300 a hookah. The method includes downwardly drawing 302 indirectly-combusted tobacco smoke from a hookah burner into an elongate dry smoke conduit of the hookah stem into a liquid within the interior of a hookah bottle using the hookah hose releasably affixed to, and in gaseous communication with a wet smoke conduit of, the hookah stem. Then one aggregates 304 a substantial amount of wetted tobacco smoke within the hookah bottle above the liquid and below the transverse wall of the hookah stem. Then one urges 306 air from the hookah hose through the wet smoke smoke conduit into the bottle interior to create positive bottle pressure. Wetted tobacco smoke is directed 308 into the pressure-actuated check valve, co-planar with said bottle and in gaseous communication with the dry smoke conduit of the stem, with a wet smoke entry exposed to the bottle interior and adapted to selectively impede, during neutral and negative bottle pressure events, and allow, during positive bottle pressure events, gaseous communication from the wet smoke entry to the wet smoke intake. Wetted tobacco smoke is directed 308 upwardly through the dry smoke conduit toward and through the hookah burner.

Turning now to FIGS. 13-17, including FIGS. 17A and 17B, an embodiment of the hookah 100 is disclosed whereby the check valve is located about the primary stem (the “primary stem embodiment”). In the embodiments of FIGS. 1-12 (the “lower stem embodiments”), the check valve 150 was positioned on the down tube 140, which positioned the check valve immediately in the bottle 102 for direct access to the wetted smoke of the bottle interior 104. The primary check valve embodiments, however, include the check valve on, within, or otherwise in contact with the primary stem via apertures.

The check valve 150 may be fitted into wet smoke outlets 134 as has been described in prior patents issued to the inventor. The primary check valve embodiments, however, require access to the dry smoke conduit 190, and for embodiments in which a check valve is placed within a wet smoke outlet 134, it is preferred that plenum include dedicated apertures to use with the check valve 150. The hookah of FIGS. 13-17 includes such dedicated apertures: the wet smoke entry 154 and wet smoke intake 156 are channeled into the stem 110 in the area of the plenum 130. Because the check valve 150 includes components mechanically indisposed to permitting reverse leakage, this is an acceptable fit; however, apertures may need to be designed in concert with proprietary hose fittings 132 that prevent reverse leakage. One way to prevent reverse leakage is through the design of surfaces in hose fittings that do not contact the wet smoke intake 156, but do contact the wet smoke entry 154; such an arrangement would permit a hose fitting to draw smoke without leaking the wetted smoke to the dry smoke conduit 190. The check valve body 152 may be constructed to allow access to the both the wet smoke entry 154 and the wet smoke intake 156.

The check valve 150 of the depicted embodiment of the present invention includes a separable body 152 a, 152 b. A first body portion 152 a is affixed to the stem 110, preferably in a permanent state, and permits a second body portion 152 b to releasably affix to the first body portion 152 a. The stem 110 includes a wet smoke conduit 136 b in the same manner as the wet smoke conduit 136 that accesses a hose fitting 132. The wet smoke conduit 136 leading directly from the bottle interior 104, through the stem, directly access the wet smoke entry 154. The wet smoke entry 154 accesses wetted smoke in all pressure situations. During positive pressure events, the operative element, here a spherical impediment 158, is dislocated, FIGS. 15-16, to allow wetted smoke to access the wet smoke intake 156 from the wet smoke entry 154. The wet smoke intake 156 in the present embodiment is in direct access to a channeled wet smoke conduit 136 b that leads back to the dry smoke conduit 190. In operation, a user that wishes to purge wetted smoke would blow into her hose, which would urge air down the wet smoke conduit 136 accessing the hose, to create a turbulent environment within the bottle interior that urges wetted smoke up the wet smoke conduit 136 accessing the check valve 150. The impediment 158 of the check valve dislocates to urge stale smoke from the wet smoke entry 154 to the wet smoke intake 156 that then accesses the wet smoke conduit 136 b that leads to the dry smoke conduit 190. From the dry smoke conduit 190, the wetted smoke is jetted upwards towards any bowl affixed to the stem 110.

The check valve 150 depicted may include differential sizing between the first portion 152 a and the second portion 152 b. The first portion 152 a may be sized to restrict the passage of the impediment 158 therein, while the second portion 152 b may be sized to allow the impediment to freely float therein. This check valve embodiment relies on gravity to maintain the pressure advantages of the present invention, thus the larger sizing of the second portion only permits free access during positive pressure events. Separating the wet smoke intake 156 from the wet smoke entry 154 is a valve partition 152 c integrated into the check valve body first portion 152 a. The valve partition 152 c may be a wall constructed of the same material as the valve body portions 152 a, 152 b that seals the wet smoke intake 156 from the wet smoke entry 154. The valve 150 may be disassembled by removing the pressure fit of the second portion 152 b from the first portion 152 a. Because the impediment is held in place by gravity, it may simply be removed to permit facile cleaning of the valve and related components.

The primary valve embodiment of FIGS. 13-17 features dedicated passages within, or around the plenum, that apply purely to the shunting of wetted smoke from the plenum to the dry smoke conduit. Turning now to FIGS. 18-23, a primary valve embodiment of the hookah 100 of the present invention is depicted that lacks the dedicated plenum channeling. The hookah 100 includes wet smoke conduits 136 that may be universally applied to non-proprietary hose fittings 132 or check valves 150 alike. When the check valve fits into the wet smoke outlet 134 into which a hose fitting can likewise fit, such outlets are considered in the present disclosure to have a universal fitting. Here, the check valve 150 includes a first portion 152 a and a second portion 152 b. Rather than feature a dedicated wet smoke conduit within, or around the plenum, the valve 150 releases wetted smoke into a wet smoke intake 156 located distant from the check valve 150. Here, the wet smoke intake 156 is positioned in the upper portion of the stem between the plenum and the burner support. The wet smoke intake 156 may be channeled from an exterior location into the stem 110 until the dry smoke conduit 190 is contacted. A retainer 159 may be positioned about the intake 156 to permit the attachment of an extension conduit 157.

The extension conduit 157 of the present invention is a passage for the distant shunted of wetted smoke from the valve to an external location of the stem 110. The preferred extension conduit is constructed of a flexible plastic capable of the bending and flexing necessitated for the use thereof. The second portion 152 b of the valve body includes a retainer 159 that accepts the periphery of the extension conduit 157 and may be sized to be similar to the retainer 159 of the stem 110. The preferred retainer includes a nipple attachment feature that utilizes an interference fit to exploit the flexible properties of the extension conduit 157 to create a sealed fit. The second portion 152 b may be attached to the first portion 152 a of the valve body by pressure fit, by threading, or other acceptable means. An advantage of the extension conduit 157 is the simplified manufacturing of the hookah, relative to embodiments that utilize extensive channeling within the plenum.

The wet smoke conduit 136 leading directly from the bottle interior 104, through the stem, directly access the wet smoke entry 154. The wet smoke entry 154 accesses wetted smoke in all pressure situations. During positive pressure events, the operative element, here a spherical impediment 158, is dislocated, FIGS. 20-21, to allow wetted smoke to access the wet smoke intake 156 from the wet smoke entry 154. Because no specialized internal plenum channeling is present, there is no need for a partition that divides the wet smoke intake 156 from the wet smoke entry 154. The wet smoke intake 156 of the present embodiment is in direct access to extension conduit 157 that leads back to the dry smoke conduit 190. In operation, a user that wishes to purge wetted smoke would blow into her hose, which would urge air down the wet smoke conduit 136 accessing the hose, creating a turbulent environment within the bottle interior that urges wetted smoke up the wet smoke conduit 136 accessing the check valve 150. The impediment 158 of the check valve dislocates urging stale smoke from the wet smoke entry 154 to the wet smoke intake 156 that then access the extension conduit 157 that leads to the dry smoke conduit 190. From the dry smoke conduit 190, the wetted smoke is jetted upwards towards any bowl affixed to the stem 110.

Turning now to FIGS. 24-27, the present invention includes a check valve 150 inaccessibly located within the body of the stem 110. This arrangement may be preferred in embodiments that emphasize the maximum amount of hose fittings. The check valve 150 includes a weighted impediment 158 shaped to fit within the contour of the wet smoke entry 154, and upon experiencing a positive pressure event, dislocates to permit fluid communication between the wet smoke entry 154 and the wet smoke intake 156. Here, the wet smoke intake 156 and wet smoke entry 154 are channeled into the interior of the plenum of the stem 110 in the same manner as wet smoke conduits 136. In the present embodiment, the distinction between wet smoke conduit 136 and the valve apertures 154, 156 become blurred and it is more useful to discuss the channels on the basis of their function as valve apertures 154, 156.

During positive pressure events, the operative element 158 is dislocated, FIGS. 26-27 to allow wetted smoke to access the wet smoke intake 156 from the wet smoke entry 154. The wet smoke intake 156 in the present embodiment is in direct access to the dry smoke conduit 190. In operation, a user that wishes to purge wetted smoke would blow into her hose, which would urge air down the wet smoke conduit 136 accessing the hose, creating a turbulent environment within the bottle interior that urges wetted smoke up the wet smoke entry 154 accessing the check valve 150. The impediment 158 of the check valve dislocates urging stale smoke from the wet smoke entry 154 to the wet smoke intake 156 that leads to the dry smoke conduit 190. From the dry smoke conduit 190, the wetted smoke is jetted upwards towards any bowl affixed to the stem 110.

The check valves 150 for any of the above-mentioned embodiments may be used as may be advantageous in given situations. Irrespective of whether the check valve is positioned on the down tube or upon/within/etc. the primary stem, check valves (with appropriate modifications to the wet smoke intake 156 and wet smoke entry 154), may be used so long as their effectiveness suggests.

A significant concern of hookahs that differentiates them from other smoking devices is the generally distinct division between dry smoke conduits and wet smoke conduits. Specifically, where pressurized environments are concerned, the wet smoke areas (e.g., in most commercial hookahs, the volume within the bottle and such portions of the stem that contact wet smoke) may often experience identical forces as the dry smoke areas (e.g., in most commercial hookahs, the downward channel of the stem). Although the nature of the force is identical, the magnitude of the forces are not. The use of liquid within the bottle creates a substantial barrier to the transmission of positive pressure from a user to the hookahs interior components. The draw pressure of a hookah user creates negative pressure within the plenum, of the present embodiment, but also a negative pressure within the dry smoke conduit. However, the magnitude of pressure should be greater in the wet smoke areas of the plenum than the dry smoke conduit. So, for example, in the hookah of FIGS. 26-27, the application of negative pressure creates a negative force on both sides of the impediment 158, each struggling to urge the impediment 158 in the direction of the forces. Because the force that derives from the hookah hose is more immediately felt in the wetted smoke areas, that force will usually prevail. In negative pressure events, the force will seal the connection between the wet smoke areas and the dry smoke conduit, but in positive pressure events, the force will result in a substantial bypass of the liquid barrier to the wet smoke entry and wet smoke intake. Because the liquid within the bottle will act as a downward barrier to the egress of wetted smoke in the dry smoke conduit, the least resistive path of egress is upward through the hookah stem's dry smoke conduit.

Turning now to FIG. 28, an embodiment explored for commercial use is depicted. Similar in nature to the embodiment depicted in FIGS. 24-27, the present invention includes a check valve 150 inaccessibly located within the body of the stem 110. This arrangement may be preferred in embodiments that emphasize the maximum amount of hose fittings. The check valve 150 includes a spherical impediment 158 shaped to block the apex of the wet smoke entry 154, and upon experiencing a positive pressure event, dislocates to permit fluid communication between the wet smoke entry 154 and the wet smoke intake 156. In the present embodiment, the distinction between wet smoke conduit 136 and the valve apertures 154, 156 become blurred and it is more useful to discuss the channels on the basis of their function as valve apertures 154, 156.

During positive pressure events, the operative element 158 is dislocated to allow wetted smoke to access the wet smoke intake 156 from the wet smoke entry 154. The wet smoke intake 156 in the present embodiment is in direct access to the dry smoke conduit 190. In operation, a user that wishes to purge wetted smoke would blow into her hose, which would urge air down the wet smoke conduit 136 accessing the hose, creating a turbulent environment within the bottle interior that urges wetted smoke up the wet smoke entry 154 accessing the check valve 150. The impediment 158 of the check valve dislocates urging stale smoke from the wet smoke entry 154 to the wet smoke intake 156 that leads to the dry smoke conduit 190. From the dry smoke conduit 190, the wetted smoke is jetted upwards towards any bowl affixed to the stem 110.

Although the present invention has been described in considerable detail with reference to certain preferred versions thereof, other versions would be readily apparent to those of ordinary skill in the art. Therefore, the spirit and scope of the appended claims should not be limited to the description of the preferred versions contained herein.

INDUSTRIAL APPLICABILITY

The present invention allows a user to enjoy hookah smoking by providing an efficient means of purging the hookah of stale, wetted smoke. A hookah may be used in a sealed state longer, and with greater effectiveness, prior to disassembly. The flavors of the tobacco product used with the hookah are less likely to be adversely affected by lingering wetted smoke. 

What is claimed is:
 1. A hookah comprising: a hookah bottle having a solid sidewall defining a bottle interior and a bottle neck; a hookah stem releasably affixable to said hookah bottle, said stem comprising: a primary stem, positioned above said bottle neck, adapted to hold a hookah burner and defining: a central, substantially-vertical dry smoke conduit bounded by a dry smoke inlet and a lower dry smoke outlet formed by a transverse stem wall; and a wet smoke conduit bounded by a wet smoke inlet and a peripheral wet smoke outlet above said bottle neck; a down tube, affixed to said dry smoke outlet and further defining said dry smoke conduit, terminating in a lower dry smoke release aperture, dimensioned to extend into said hookah bottle to a penetration depth at least half of a bottle height; a pressure-actuated check valve, positioned upon said primary stem and in gaseous communication with said bottle interior, with a wet smoke entry exposed to said bottle interior and a wet smoke intake in direct gaseous communication with said dry smoke inlet, and adapted to selectively impede, during neutral and negative bottle pressure events, and allow, during positive bottle pressure events, gaseous communication from said wet smoke entry to said wet smoke intake; and a hose fitting, affixed to said wet smoke outlet, for the releasable affixation of a hookah hose to said hookah stem.
 2. The hookah of claim 1 wherein said wet smoke intake includes an external pressure conduit.
 3. The hookah of claim 2 wherein said wet smoke intake is positioned above said down tube and below said dry smoke inlet.
 4. The hookah of claim 1 wherein said check valve includes a movable impediment.
 5. The hookah of claim 4 wherein said check valve includes a removable case exposing said movable impediment.
 6. The hookah of claim 1 wherein said stem includes universal hose fittings, and wherein said check valve is adapted to removable affix to said universal hose fittings.
 7. The hookah of claim 7 wherein said check valve includes an external pressure conduit, and wherein said primary stem includes a radial wet smoke inlet in gaseous communication with said dry smoke inlet.
 8. The hookah of claim 7 wherein said external pressure conduit is flexible.
 9. A hookah comprising: a hookah bottle having a solid sidewall defining a bottle interior and a bottle neck; a hookah stem releasably affixable to said hookah bottle, said stem comprising: a primary stem, positioned above said bottle neck, adapted to hold a hookah burner and defining: a central, substantially-vertical dry smoke conduit bounded by a dry smoke inlet and a lower dry smoke outlet formed by a transverse stem wall; and a wet smoke conduit bounded by a wet smoke inlet and a peripheral wet smoke outlet above said bottle neck; a down tube, affixed to said dry smoke outlet and further defining said dry smoke conduit, terminating in a lower dry smoke release aperture, dimensioned to extend into said hookah bottle to a penetration depth at least half of a bottle height; a pressure-actuated check valve with a wet smoke entry, within said primary stem, exposed to said bottle interior and a wet smoke intake, within said primary stem, in direct gaseous communication with said dry smoke inlet, and adapted to selectively impede, during neutral and negative bottle pressure events, and allow, during positive bottle pressure events, gaseous communication from said wet smoke entry to said wet smoke intake; and a hose fitting, affixed to said wet smoke outlet, for the releasable affixation of a hookah hose to said hookah stem.
 10. The hookah of claim 9 wherein said check valve includes said wet smoke intake directly contacting said dry smoke inlet of said primary stem.
 11. The hookah of claim 10 wherein said check valve includes said wet smoke entry directly contacting said bottle interior through said primary stem.
 12. The hookah of claim 11 wherein said check valve includes a physical, movable impediment that dislocates to provide access between said dry smoke inlet and said wet smoke entry during said positive pressure event.
 13. The hookah of claim 9 wherein said check valve is embedded within said plenum to include a substantially vertical wet smoke entry that, in positive pressure, events is in gaseous communication with a substantially horizontal wet smoke intake.
 14. The hookah of claim 13 wherein said wet smoke intake accesses said dry smoke conduit above said down tube. 